Gas burner for a household appliance

ABSTRACT

A compact thermoelectric safety actuator having a first body with a first cavity and a second body with a second cavity. The first and second bodies are connected so that the first and second cavities are arranged facing and open to one another. The first body has a gas outlet and the second body has a gas inlet in fluid communication with the gas outlet through the second cavity, An electromagnet of the actuator has a first end portion residing in the first cavity and a second end portion residing in the second cavity. A rotatable arm has a first end with a ferromagnetic frame adapted to engage the second portion of the electromagnet and a second end coupled to a sealing member, each of the tilting arm, ferromagnetic frame and sealing member are arranged in the second cavity. The first sealing member is configured to seat against a seating located on the first body when the arm is in a rest position, the first seating being located between the gas outlet and the second cavity.

CROSS-REFERENCE TO RELATED APPLICATIONS

The Present application relates to and claims the benefit and priority to PCT/EP2012/061018, filed Jun. 11, 2012 which claims the benefit and priority to Spanish Patent Application No. P201131008, filed Jun. 15, 2011.

TECHNICAL FIELD

The invention relates to a gas burner for a household appliance, in particular for an oven, stoves or other household appliance that are preferably supplied with natural gas or LPG.

BACKGROUND

There are known gas burners for household appliances that include thermoelectric safety devices that close the passage of gas towards the burner in the absence of flame. Thermoelectric safety devices comprise magnetic units connected to a corresponding thermocouple, with the result that for as long as there is a flame in the burner, the corresponding flame thermocouple keeps the corresponding magnetic unit energized, and as a result, the thermoelectric device allows the passage of gas towards the burner. In the absence of flame, the thermocouple cools and is not able to maintain the delivery of power to the magnetic unit, as a result of which the magnetic unit is de-energized, closing the passage of gas towards the burner.

From the moment the burner is lit until the thermocouple is able to keep the magnetic unit energized a period of time elapses, as a result of which it is necessary that the thermoelectric device comprises auxiliary means that, once the magnetic unit has been reset manually, allow the magnetic unit to be kept energized until the thermocouple is able to do so by itself.

In general terms, thermoelectric safety devices are arranged removed from the burner close to the controls as described in U.S. Pat. No. 6,886,581 B2. The magnetic unit is arranged housed in a gas valve body, the magnetic unit being substantially aligned with a shaft of the valve body, with the result that the user must activate the control of the valve body coupled to the shaft so that said shaft acts on the magnetic unit, keeping it in the open or passage-of-gas position until the thermocouple, arranged close to a burner injector, is able to keep said magnetic unit energized.

SUMMARY OF THE DISCLOSURE

According to one implementation a gas burner is provided that comprises at least one casing, at least one thermocouple, at least one injector supplied with a gas and fixed to the casing, and at least one thermoelectric safety actuator adapted to open or close the passage of gas towards the injector. The thermoelectric safety actuator is arranged fixed to the casing and comprises a body, at least one inlet gas conduit, at least one outlet gas conduit connected to the injector, at least one electromagnet housed in the inside of the body and arranged connected to the thermocouple, at least one tilting arm that is arranged fixed with a frame on one end and a sealing member on the opposite end. The arm tilts between a rest position in which the passage of gas from the inlet conduit towards the outlet conduit is closed by means of said sealing member, and an activation position, in which the electromagnet is energized and the passage of gas open, the electromagnet being energized initially by auxiliary energization means and being kept energized by said auxiliary energization means until the thermocouple is able to keep said electromagnet energized.

As a result, an optimised and compact gas burner is obtained, and which comprises the thermoelectric safety actuator close to the injector and the thermocouple, thereby reducing the lengths and the number of conduits necessary. A burner with fewer load losses is also obtained.

These and other advantages and characteristics will be made evident in the light of the drawings and the detailed description thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a view in perspective of a burner according to one embodiment.

FIG. 2 shows a sectional view of the burner shown in FIG. 1.

FIG. 3 shows a sectional view of a safety actuator comprised in the burner shown in FIG. 1.

FIG. 4 shows a view in perspective of a safety actuator comprised in the burner shown in FIG. 1.

FIG. 5 shows a sectional view of a safety actuator of a burner according to a second embodiment.

FIG. 6 shows a view in perspective of the safety actuator shown in FIG. 5.

FIG. 7 shows a view in perspective of a safety actuator of a burner according to a third embodiment.

DETAILED DESCRIPTION

FIG. 1 shows a first embodiment of a gas burner 1 of a cooking appliance, preferably of an oven or a gas stove, which comprises a casing 5, a thermocouple 4, an injector 2 supplied with a gas and fixed to the casing 5, and a mixing conduit 6 connected to the injector 2, wherein the gas that arrives through the injector 2 is mixed with the air, said mixture exiting through holes 6 c arranged along a substantially flat surface 6 b of the mixing conduit 6. The gas burner 1 also comprises a spark plug 3, arranged substantially parallel to the substantially flat surface 6 b of the mixing conduit 6, which causes the necessary spark in the gas burner 1 to cause the ignition of the gas and air mixture, the spark plug 3 being activated by auxiliary energization means.

In the embodiment shown in FIGS. 1 and 2, the thermocouple 4 and the spark plug 3 are arranged substantially parallel to each other, being extended on the substantially flat surface 6 b by a certain distance. Both the thermocouple 4 and the spark plug 3 are arranged fixed to the casing 5, in particular to respective extensions 5 a, 5 c of the casing 5 substantially in the shape of an L.

The gas burner 1 also comprises a thermoelectric safety actuator 20, shown in detail in FIGS. 3 and 4, adapted to open or close the passage of gas towards the injector 2. The thermoelectric safety actuator 20 is arranged fixed to the casing 5 and comprises an inlet gas conduit 23, an outlet gas conduit 25, a body 21,22 inside which is housed an electromagnet 36 adapted to be connected to the thermocouple 4, a tilting arm 38 on one of the ends of which is arranged fixed a frame 37 and on the other end of which is arranged fixed a sealing member 35, the tilting arm 38 tilting between a rest position in which the passage of gas from the inlet conduit 23 towards the outlet conduit 25 is closed by means of said sealing member 35, and an activation position in which the electromagnet 36 is energized by the thermocouple 4 and the passage of gas is open. The electromagnet 36 is energized initially by auxiliary energization means, it being kept energized by said auxiliary energization means until the thermocouple 4 is able to keep said electromagnet 36 energized by itself.

In the embodiment shown in FIGS. 1 and 2, the injector 2 is arranged coupled to the thermoelectric safety actuator 20.

According to one implementation the electromagnet 36 includes a core 36 a, preferably in the shape of a U, and a single coil 36 b wound around the core 36 a. The frame 37 is ferromagnetic and closes against free transverse surfaces 36 c of the core 36 a when said electromagnet 36 is energized by the thermocouple 4.

The body 21, 22 of the thermoelectric safety actuator 20, shown in detail in FIGS. 3 and 4, comprises a first member 22 that comprises the outlet conduit 25, and a second member 21 that comprises the inlet conduit 23. According to one implementation both the first member 22 and the second member 21 are substantially cylindrical, each one of them comprising a substantially flat contact surface 21 a, 22 a on which are fixed both members 21, 22. According to on implementation the inlet conduit 23 and the outlet conduit 25 are arranged substantially parallel to each other. The second member 21 comprises a groove 30 that extends along a closed contour on the contact surface 21 a, there being housed in said groove 30 a gasket 29 that seals the closure between both contact surfaces 21 a, 22 a. The first member 22 and the second member 21 each have ears 22 b, 21 b, shown in FIG. 1, with respective holes through which the first member 22 and the second member 21 are fixed to each other by means of fixing means, said fixing means comprising in the embodiment shown in FIGS. 1 and 4, respective screws 32.

According to one implementation the first member 22 comprises a substantially cylindrical first housing 27, in which is partially housed the electromagnet 36 projecting out partially in relation to the support surface 22 a, and a seating 28 that projects out in relation to the support surface 22 a, from one end of the outlet conduit 25. According to one implementation the first housing 27 and the outlet conduit 25 are arranged substantially parallel to each other. The injector 2 is arranged coupled to the outlet conduit 25 of said thermoelectric safety actuator 20.

According to one implementation the first housing 27 includes a first part 27 a with a smaller cross-section in which is housed supported one end of the core 36 a of the electromagnet 36. Additionally, the first member 22 comprises a second housing 26, substantially coaxially to the first housing 27, which extends from a base 22 c, substantially parallel and opposite to the support surface 22 a, the first housing 27 being connected to the outside of the first member 22. In said second housing 26 is arranged inserted a connection terminal 31 connected to one end 36 d of the coil 36 b and a gasket 33 that seals said second housing 26. The connection terminal 31 projects out in relation to the base 22 c, it being adapted to be connected by a connection terminal 7 b of a cable 7 to the thermocouple 4 as shown in FIG. 1.

In addition, the second member 21 comprises a housing 24 in which is partially housed the tilting arm 38 along with the frame 37 and the sealing member 35. The tilting arm 38 is arranged fixed to the first member 22 by fixing means. In the embodiment shown, the fixing means comprise screws 34, shown in FIG. 3, although in other embodiments they may comprise another type of known fixing means. The tilting arm 38 has a fixed first part 38 a and a second part 38 b that is movable in relation to said first part 38 a, there being arranged on the second part 38 b, which is substantially flat, the frame 37 and the sealing member 35.

The tilting arm 38 also comprises elastic means arranged between the first part 38 a and the second part 38 b, which allows the tilting arm 38 to be returned from the activation position, in which the frame 37 is in contact with the core 36 a of the electromagnet 36, to the rest position in which a substantially flat surface 35 b of the sealing member 35 closes, against the seating 28 to prevent the passage of gas towards the outlet conduit 25. The elastic means comprise a compression spring 39, the spring 39 being arranged coupled to the first part 38 a by a projection 38 f and to the second part 38 b by the corresponding projection 38 e, shown in FIG. 3. Furthermore, the second part 38 b has tabs 38 c, shown in FIG. 3, each one of which cooperates with a corresponding groove 38 d that extends along the first part 38 a, in a direction substantially orthogonal to the second part 38 b, guiding the movement and the rotation of the second part 38 b in relation to the first part 38 a.

When the user activates a control to light the corresponding burner 6, the control sends the corresponding command to an electronic driver so that it provides the necessary electrical energy to the electromagnet 36 for it to be energized, attracting the frame 37 without the need for the user to act directly on the electromagnet by having to move the frame 37 against the electromagnet 36 manually. The electronic driver provides the electrical energy necessary to attract the frame 37 towards the electromagnet 36 and keep it energized for a specific period of time while it acts on the spark plug 3 so that the necessary sparks are generated. If the flame has been lit, the thermocouple 4 is heated, generating in turn electrical energy with which the electromagnet 36 is supplied so that it remains energized while there is a flame. As soon as there is no flame or when the flame is insufficient for the thermocouple 4 to generate enough electrical energy to keep the electromagnet 36 energized, the tilting arm 38 of the actuator 20 moves into the rest position, closing the passage of gas towards the burner 6.

In a second embodiment of the gas burner, not shown as a whole in the figures, the gas burner is adapted to a household oven with grill for its operation as a conventional oven or with the grill function, comprising a casing, a thermocouple, a spark plug, an injector for supplying a gas and fixed to the casing, and a mixing conduit connected to the injector, wherein the gas that arrives through the injector is mixed with the air, of similar characteristics to the gas burner 1 described in the first embodiment and shown in FIGS. 1 and 2. The gas burner of the second embodiment also comprises the following additional members: a thermocouple, an injector, a spark plug, a mixing conduit and a support similar to the one described above, as a result of which they will not be described in detail. Said additional members will be used when the oven operates with the grill function. The gas burner of this second embodiment comprises a single thermoelectric safety actuator 40, shown in FIGS. 5 and 6, which supplies both injectors, and is described below.

The thermoelectric safety actuator 40 comprises a body 41,42 that has two first members 42, similar to the first member 22 described in the first embodiment, and shown in detail in FIG. 4, and an intermediate member 41 arranged between both first members 42.

Each first member 42 comprises an outlet conduit 45, while the intermediate member 41 comprises an inlet conduit 43. According to one implementation the inlet conduit 43 is substantially orthogonal to the outlet conduits 45. According to one implementation both the first members 42 and the intermediate member 41 are substantially cylindrical, each one of them comprising, on one end, a substantially flat contact surface 41 a, 42 a on which first members 42 are fixed to each other by the intermediate member 41. The intermediate member 41 comprises a groove 50 that extends along a closed contour in each of the two contact surfaces 41 a, there being housed in said groove 50 a respective gasket 49 that seals the closure between both contact surfaces 41 a, 42 a. The intermediate member 41 and the first members 42 each have ears 41 b, 42 b, shown in FIG. 6, with respective holes through which the first members 42 are fixed to the intermediate member 41 by respective screws 52.

According to one implementation each first member 42 comprises a substantially cylindrical first housing 47 in which is partially housed an electromagnet 56 projecting out partially in relation to the support surface 42 a, and a seating 48 that projects out in relation to the support surface 42 a from one end of the outlet conduit 45. According to one implementation the first housing 47 and the outlet conduit 45 are arranged substantially parallel to each other. Each injector is coupled to the outlet conduit 45 of the corresponding first member 42 of said thermoelectric safety actuator 40.

Additionally, the first housing 47 includes a first part 47 a with a smaller cross-section in which is housed supported one end of a core 56 a of the electromagnet 56. In addition, the first member 42 comprises a second housing 46, substantially coaxially to the first housing 47, which extends from a base 42 c, substantially parallel and opposite to the support surface 42 a, and which is connected to the outside of the first member 42. In said second housing 46 a connection terminal 51 is arranged inserted, connected to one end 56 d of a coil 56 b of the electromagnet 56, and a gasket 53 that seals said second housing 46. The connection terminal 51 projects out in relation to the base 42 c, it being adapted to be connected by a respective connection terminal to the respective thermocouple.

Furthermore, the intermediate member 41 comprises a housing 44 in which tilting arms 58 along with frames 57 and respective sealing members 55 are partially housed.

Each tilting arm 58, similar to the arm 38 of the first embodiment, is arranged fixed to the first member 42 by means of fixing means that comprise, in the embodiment shown in FIG. 5, screws 54. Each tilting arm 58 has a fixed first part 58 a and a second part 58 b that is movable in relation to said first part 58 a, the frame 57 and the sealing member 55 being arranged fixed on each end of the second part 58 b, which, according to one implementation, is substantially flat.

Each tilting arm 58 also comprises elastic means arranged between the first part 58 a and the second part 58 b, which allow the tilting arm 58 to be returned from the activation position, in which the corresponding frame 57 is in contact with the core 56 a of the corresponding electromagnet 56, to the rest position in which a substantially flat surface 55 b of the sealing member 55 closes against a seating 48 of the first member 42 to prevent the passage of gas towards the corresponding outlet conduit 45. The elastic means comprise a compression spring 59, the spring 59 being arranged coupled to the first part 58 a by a projection 58 e and to the second part 58 b by the corresponding projection 58 f, as shown in FIG. 5. In addition, the second part 58 b has tabs, not shown in the figures, similar to those described in the first embodiment, each one of which cooperates with a corresponding groove 58 d that extends in the first part 58 a in a direction substantially orthogonal to the second part 58 b, guiding the movement and the rotation of the second part 58 b in relation to the first part 58 a.

The thermoelectric safety actuator 40 is arranged coupled to a ramp through which the gas is supplied, the gas being supplied from the respective inlet conduit 43 to the respective injector.

In a third embodiment of the invention, the gas burner is similar to the one shown in FIG. 1, comprising the members described in the first embodiment, the thermoelectric safety actuator 20 shown in FIGS. 1 to 4 being replaced by the thermoelectric safety actuator 60 shown in FIG. 7 and which is described below.

The thermoelectric safety actuator 60 is arranged fixed to the casing 5 and comprises an inlet gas conduit 63, an outlet gas conduit 65, a body 61,62 inside which is housed an electromagnet 76 adapted to be connected to the thermocouple 4, a tilting arm 78 on one of the ends of which is arranged fixed a frame 77 and on the other end of which is arranged fixed a sealing member 75, the tilting arm 78 tilting between a rest position in which the passage of gas from the inlet conduit 63 towards the outlet conduit 65 is closed by means of said sealing member 75 and an activation position, in which the electromagnet 76 is energized by the thermocouple 4 and the passage of gas is open. The electromagnet 76 is energized initially by auxiliary energization means, it being kept energized by said auxiliary energization means until the thermocouple 4 is able to keep said electromagnet 76 energized.

According to one implementation the electromagnet 76 includes a core 76 a, preferably in the shape of a U, and a single coil 76 b wound around the core 76 a. The frame 77 is ferromagnetic and closes against free transverse surfaces 76 c of the core 76 a when said electromagnet 76 is energized by the thermocouple 4.

Furthermore, the body 61,62 of the thermoelectric safety actuator 60 comprises a first member 62 that comprises the outlet conduit 65, and a second member 61 that comprises the inlet conduit 63. According to one implementation both the first member 62 and the second member 61 are substantially cylindrical, each one of them comprising a substantially flat contact surface 61 a, 62 a on which are fixed both members 61,62. The second member 61 comprises a groove 70 that extends along a closed contour on the contact surface 61 a, there being housed in said groove 70 a gasket 69 that seals the closure between both contact surfaces 61 a, 62 a. According to one implementation the first member 61 and the second member 62 each have ears, not shown in the figures and similar to those of the safety actuator 20 of the first embodiment, by means of which the first member 62 and the second member 61 are fixed to each other.

According to one implementation the first member 62 comprises a substantially cylindrical first housing 67 in which is partially housed the electromagnet 76 projecting out partially in relation to the support surface 62 a, and a seating 68 that projects out in relation to the support surface 62 a from one end of the outlet conduit 65. According to one implementation the first housing 67 and the outlet conduit 65 are arranged substantially parallel to each other. The injector 2 is arranged coupled to the outlet conduit 65 of said thermoelectric safety actuator 60.

Additionally, the first housing 67 includes a first part 67 a with a smaller cross-section in which is housed supported one end of the core 76 a of the electromagnet 76. In addition, the first member 62 comprises a second housing 66, substantially coaxially to the first housing 67, which extends from a base 67 b arranged on the opposite end to the support surface 62 a, and which is connected to the outside of the first member 62. In said second housing 66 is arranged inserted a connection terminal 71 connected to one end 76 d of the coil 76 b and a gasket 73 that seals said second housing 66. According to one implementation the connection terminal 71 projects out in relation to the base 67 b, the connection terminal 71 being adapted to be connected by a connection terminal 7 b of a cable 7 to the thermocouple 4, as shown in FIG. 1.

Furthermore, the second member 61 comprises a housing 64 in which is at least partially housed the tilting arm 78 along with the frame 77 and the sealing member 75.

The tilting arm 78 is arranged fixed to the first member 62 in a similar way to that described in the first embodiment. The tilting arm 78 has a fixed first part 78 a and a second part 78 b that is movable in relation to said first part 78 a, there being arranged fixed on the second part 78 b, which is, according to one implementation, substantially flat, the frame 77 and the sealing member 75.

The tilting arm 78 also comprises elastic means arranged between the first part 78 a and the second part 78 b, which allow the tilting arm 78 to be returned from the activation position in which the frame 77 is in contact with the core 76 a of the electromagnet 76 to the rest position in which a substantially flat surface 75 a of the sealing member closes, against the seating 68 to prevent the passage of gas towards the outlet conduit 65. According to one implementation the elastic means comprise a compression spring 79, the spring 79 being arranged coupled to the first part 78 a by a projection 78 e and to the second part 78 b by the corresponding projection 78 f. In addition, the second part 78 b has tabs, not shown in FIG. 7, similar to the tabs shown in FIG. 3, described in the first embodiment, each one of which cooperates with a corresponding groove 78 d that extends in the first part 78 a, the grooves 78 d extending in a direction substantially orthogonal to the second part 78 b guiding the movement and the rotation of the second part 78 b in relation to the first part 78 a.

The thermostatic safety actuator 60 also comprises an electromagnetic unit 81, which is known in the art and will not therefore be described in detail. The electromagnetic unit 81 is arranged housed at least partially in a second housing 85 of the second member 61 of the body 61,62. According to one implementation said second housing 85 is arranged substantially coaxially to the first housing 64, the second housing 85 including a seating 84 against which it closes a sealing member 82 of electromagnetic unit 81 in a disconnection position when said electromagnetic unit 81 is not supplied with electrical energy. The electromagnetic unit 81 is arranged inserted in the second member 61, the thermostatic safety actuator 60 including a closure member 83 that is arranged threaded to an outer surface of the second housing 85 and which keeps the magnetic unit 81 inside said second housing 85. In this embodiment, the inlet gas conduit 63 connects to the second housing 85 of the second member 61. According to one implementation the inlet conduit 63 is arranged substantially orthogonal to the outlet conduit 65.

The thermostatic safety actuator 60 described in this embodiment provides a double safety aspect, as firstly, when there is no flame or when the flame is not sufficient for the thermocouple 4 to generate enough energy to keep the electromagnet 76 energized, the sealing member 75 closes against the seating 68 the outlet conduit 65, with no gas being supplied to the injector 2, which is arranged inserted partially in the outlet conduit 65. Secondly, in the event of a power cut, the electromagnetic unit 81 ensures the supply of gas to the injector 2 is cut, as the sealing member 82 of the electromagnetic unit 81 closes, against the seating 84, the passage of gas towards the outlet conduit 65.

Finally, although in the embodiments shown it is the spark plug that causes the spark, in other embodiments not shown in the figures other ignition means may be used. 

1-15. (canceled)
 16. A thermoelectric safety actuator comprising: a first body having a first cavity and a second body having a second cavity, the first and second bodies being connected so that a gas-tight seal exists between a first contact surface of the first body a second contact surface of the second body and so that the first and second cavities are arranged facing and open to one another, the first body having a gas outlet, the second body having a gas inlet in fluid communication with the gas outlet through the second cavity, an electromagnet comprising a first end portion with a first end and a second end portion with a second end, the first end portion residing in the first cavity of the first body and the second end portion residing in the second cavity of the second body, a tilting arm rotatable between a rest position when the electromagnet is de-energized and an activation position when the electromagnet is energized, the tilting arm comprising a moving part with a first end having a ferromagnetic frame and a second end coupled to a first sealing member, each of the tilting arm, ferromagnetic frame and first sealing member arranged in the second cavity of the second body, the first sealing member adapted to seat against a first seating located on the first body when the tilting arm is in the rest position, the first seating being located between the gas outlet and the second cavity, in the rest position the ferromagnetic frame of the tilting arm is located a distance apart from the second end of the electromagnet, in the activation position the ferromagnetic frame of the tilting arm being located against the second end of the electromagnet with the first sealing member being located apart from the first seating on the first body.
 17. A thermoelectric safety actuator according to claim 16, wherein an outside portion of the first body is configured to be attached directly to a casing of a gas burner.
 18. A thermoelectric safety actuator according to claim 17, wherein the gas outlet is configured to be directly connected to an inlet of an injector located in the gas burner casing.
 19. A thermoelectric safety actuator according to claim 16, wherein the gas inlet and gas outlet are arranged substantially parallel to one another.
 20. A thermoelectric safety actuator according to claim 16, wherein the first cavity of the first body and the gas outlet are arranged substantially parallel to one another.
 21. A thermoelectric safety actuator according to claim 19, wherein the first cavity of the first body and the gas outlet are arranged substantially parallel to one another.
 22. A thermoelectric safety actuator according to claim 16, wherein the first seating comprises a portion of the first body which projects into the second cavity of the second body.
 23. A thermoelectric safety actuator according to claim 16, wherein a third cavity is provided on an outside of the first body, the third cavity being arranged substantially coaxial with the first cavity, there being located in the third cavity a connection terminal connected to the electromagnet.
 24. A thermoelectric safety actuator according to claim 16, wherein the tilting arm is urged toward the rest position by a resilient member residing in the second cavity of the second body.
 25. A thermoelectric safety actuator according to claim 16, further comprising a safety shut-off valve having an electromagnetic unit, the electromagnetic unit located at least partially in the interior of the second body and comprising a movable member that moves between a first position when the electromagnet unit is energized and a second position when the electromagnetic unit is de-energized, the safety shut-off valve having a second sealing member that is connected with the moveable member, the second body having a second seating located between the gas inlet and the second cavity of the second body, when the electromagnetic unit is energized the second sealing member is positioned away from the second seating so as to permit a gas flow between the gas inlet and the second cavity of the second body, when the electromagnetic unit is de-energized the second sealing member is positioned against the second seating so as to prevent a gas flow between the gas inlet and the second cavity of the second body.
 26. A thermoelectric safety actuator according to claim 25, wherein the gas inlet and the gas outlet are arranged substantially orthogonal to one another.
 27. A gas burner assembly for a gas appliance comprising: a burner casing, an injector situated in the burner casing configured to introduce a gas into the burner, the injector having a gas inlet and a gas outlet, a thermoelectric safety actuator arranged fixed to the casing and comprising: a first body having a first cavity and a second body having a second cavity, the first and second bodies being connected so that a gas-tight seal exists between a first contact surface of the first body a second contact surface of the second body and so that the first and second cavities are arranged facing and open to one another, the first body having a gas outlet, the second body having a gas inlet in fluid communication with the gas outlet through the second cavity, the gas outlet being connected to the gas inlet of the injector via a gas-tight connection, an electromagnet comprising a first end portion with a first end and a second end portion with a second end, the first end portion residing in the first cavity of the first body and the second end portion residing in the second cavity of the second body, a tilting arm rotatable between a rest position when the electromagnet is de-energized and an activation position when the electromagnet is energized, the tilting arm comprising a moving part with a first end having a ferromagnetic frame and a second end coupled to a first sealing member, each of the tilting arm, ferromagnetic frame and first sealing member arranged in the second cavity of the second body, the first sealing member adapted to seat against a first seating located on the first body when the tilting arm is in the rest position, the first seating being located between the gas outlet and the second cavity, in the rest position the ferromagnetic frame of the tilting arm is located a distance apart from the second end of the electromagnet, in the activation position the ferromagnetic frame of the tilting arm being located against the second end of the electromagnet with the first sealing member being located apart from the first seating on the first body.
 28. A gas burner assembly according to claim 27, further comprising a thermocouple arranged adjacent the burner and adapted to supply power to the electromagnet when a flame is present in the burner.
 29. A gas burner assembly according to claim 27, wherein the gas inlet and gas outlet of the thermoelectric safety actuator are arranged substantially parallel to one another.
 30. A gas burner assembly according to claim 27, wherein the first cavity of the first body and the gas outlet are arranged substantially parallel to one another.
 31. A gas burner assembly according to claim 29, wherein the first cavity of the first body and the gas outlet are arranged substantially parallel to one another.
 32. A gas burner assembly according to claim 27, wherein the gas outlet of the thermoelectric safety actuator is directly coupled to the gas inlet of the injector.
 33. A gas burner assembly according to claim 27, wherein the first seating comprises a portion of the first body which projects into the second cavity of the second body.
 34. A gas burner assembly according to claim 27, wherein a third cavity is provided on an outside of the first body, the third cavity being arranged substantially coaxial with the first cavity, there being located in the third cavity a connection terminal connected to the electromagnet.
 35. A gas burner assembly according to claim 28, wherein a third cavity is provided on an outside of the first body, the third cavity being arranged substantially coaxial with the first cavity, there being located in the third cavity a connection terminal connected to the electromagnet, the thermocouple being electrically coupled to the connection terminal.
 36. A gas burner assembly according to claim 27, wherein the tilting arm is urged toward the rest position by a resilient member residing in the second cavity of the second body.
 37. A gas burner assembly according to claim 27, wherein the thermoelectric safety actuator further comprising a safety shut-off valve having an electromagnetic unit, the electromagnetic unit located at least partially in the interior of the second body and comprising a movable member that moves between a first position when the electromagnet unit is energized and a second position when the electromagnetic unit is de-energized, the safety shut-off valve having a second sealing member that is connected with the moveable member, the second body having a second seating located between the gas inlet and the second cavity of the second body, when the electromagnetic unit is energized the second sealing member is positioned away from the second seating so as to permit a gas flow between the gas inlet and the second cavity of the second body, when the electromagnetic unit is de-energized the second sealing member is positioned against the second seating so as to prevent a gas flow between the gas inlet and the second cavity of the second body.
 38. A gas burner assembly according to claim 37, wherein the gas inlet and the gas outlet are arranged substantially orthogonal to one another. 